First, we have analyzed the long time behavior of acoustic waves in heterogeneous media. Due to the interaction of the waves by the heterogeneities, their long-time description is challenging. We have characterised the wave to leading order by the solution of an effective wave equation for which heterogeneities are averaged out. The maximum time scale for which the result holds depends on the type of heterogeneities, and is minimal in the random setting. Capitalizing on this we have then provided lower bounds for the localization length of localized eigenvectors for the acoustic operator at the bottom of the spectrum.
Second, we have studied random suspensions I a fluid flow, and more specifically random suspensions of rigid particles in a steady Stokes flow.
In particular,
- We have rigorously derived the homogenized system for neutrally-buoyant particles, which takes the form of some Stokes fluid with an effective viscosity.
- Based on the quantitative theory, we have addressed the case of sedimenting particles and successfully defined the so-called effective sedimentation speed. This has allowed us to revisit and rigorously analyse the celebrated Caflisch-Luke paradox, and rule out this paradox under the assumption of hyperuniformity/
- We have given the most general justification of the Einstein formula for the effective viscosity (and adapt the argument to the Clausius-Mossotti formula), and developed a general theory for the expansion at arbitrary order.
- Suspensions of swimming bacteria can lead to a decrease of the effective viscosity in physical experiments. We have introduced and analysed a model for such active suspensions; and rigorously justified the drastic reduction of viscosity predicted by the physics literature and observed experimentally.
Third, we have started to extend the quantitative homogenization theory available for linear elliptic equations to the nonlinear setting, and established a quantitative two-scale expansion for random monotone operators (which model nonlinear heat conduction e.g.).
Fourth, in order to connect spectral theory of random operators to PDE analysis, we have defined and studied the correlations of the landscape function in the whole space, a tool of great practical interest in the physics of Anderson localisation.